Friction Torque on Cone Clutch from Constant Wear Theory given Semi-Cone Angle Solution

STEP 0: Pre-Calculation Summary
Formula Used
Friction Torque on Clutch = pi*Coefficient of Friction Clutch*Permissible Intensity of Pressure in Clutch*Inner Diameter of Clutch*((Outer Diameter of Clutch^2)-(Inner Diameter of Clutch^2))/(8*sin(Semi-Cone Angle of Clutch))
MT = pi*μ*pa*di*((do^2)-(di^2))/(8*sin(α))
This formula uses 1 Constants, 1 Functions, 6 Variables
Constants Used
pi - Archimedes' constant Value Taken As 3.14159265358979323846264338327950288
Functions Used
sin - Sine is a trigonometric function that describes the ratio of the length of the opposite side of a right triangle to the length of the hypotenuse., sin(Angle)
Variables Used
Friction Torque on Clutch - (Measured in Newton Meter) - Friction Torque on Clutch is the rotational force that opposes motion between the clutch's moving parts, affecting its performance and wear in a mechanical system.
Coefficient of Friction Clutch - Coefficient of Friction Clutch is a value that represents the frictional force between the clutch and the flywheel in a constant wear theory scenario.
Permissible Intensity of Pressure in Clutch - (Measured in Pascal) - Permissible Intensity of Pressure in Clutch is the maximum allowed pressure in a clutch, ensuring efficient power transmission without wear and tear, according to constant wear theory.
Inner Diameter of Clutch - (Measured in Meter) - Inner Diameter of Clutch is the diameter of the clutch that remains constant during the wear process, affecting the clutch's performance and lifespan.
Outer Diameter of Clutch - (Measured in Meter) - Outer Diameter of Clutch is the maximum diameter of the clutch that remains constant during the wear process in the constant wear theory.
Semi-Cone Angle of Clutch - (Measured in Radian) - Semi-Cone Angle of Clutch is the angle at which the clutch wears out uniformly according to the Constant Wear Theory in a semi-cone shaped clutch.
STEP 1: Convert Input(s) to Base Unit
Coefficient of Friction Clutch: 0.2 --> No Conversion Required
Permissible Intensity of Pressure in Clutch: 1.012225 Newton per Square Millimeter --> 1012225 Pascal (Check conversion ​here)
Inner Diameter of Clutch: 100 Millimeter --> 0.1 Meter (Check conversion ​here)
Outer Diameter of Clutch: 200 Millimeter --> 0.2 Meter (Check conversion ​here)
Semi-Cone Angle of Clutch: 89.9 Degree --> 1.56905099754261 Radian (Check conversion ​here)
STEP 2: Evaluate Formula
Substituting Input Values in Formula
MT = pi*μ*pa*di*((do^2)-(di^2))/(8*sin(α)) --> pi*0.2*1012225*0.1*((0.2^2)-(0.1^2))/(8*sin(1.56905099754261))
Evaluating ... ...
MT = 238.500260040072
STEP 3: Convert Result to Output's Unit
238.500260040072 Newton Meter -->238500.260040072 Newton Millimeter (Check conversion ​here)
FINAL ANSWER
238500.260040072 238500.3 Newton Millimeter <-- Friction Torque on Clutch
(Calculation completed in 00.009 seconds)

Credits

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Created by Vaibhav Malani
National Institute of Technology (NIT), Tiruchirapalli
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Verified by Sagar S Kulkarni
Dayananda Sagar College of Engineering (DSCE), Bengaluru
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Constant Wear Theory Calculators

Coefficient of Friction of Clutch from Constant Wear Theory
​ LaTeX ​ Go Coefficient of Friction Clutch = 8*Friction Torque on Clutch/(pi*Permissible Intensity of Pressure in Clutch*Inner Diameter of Clutch*((Outer Diameter of Clutch^2)-(Inner Diameter of Clutch^2)))
Permissible Pressure Intensity on Clutch from Constant Wear Theory given Axial Force
​ LaTeX ​ Go Permissible Intensity of Pressure in Clutch = 2*Axial Force for Clutch/(pi*Inner Diameter of Clutch*(Outer Diameter of Clutch-Inner Diameter of Clutch))
Axial Force on Clutch from Constant Wear Theory given Permissible Intensity of Pressure
​ LaTeX ​ Go Axial Force for Clutch = pi*Permissible Intensity of Pressure in Clutch*Inner Diameter of Clutch*(Outer Diameter of Clutch-Inner Diameter of Clutch)/2
Axial Force on Clutch from Constant Wear Theory given Friction Torque
​ LaTeX ​ Go Axial Force for Clutch = 4*Friction Torque on Clutch/(Coefficient of Friction Clutch*(Outer Diameter of Clutch+Inner Diameter of Clutch))

Friction Torque on Cone Clutch from Constant Wear Theory given Semi-Cone Angle Formula

​LaTeX ​Go
Friction Torque on Clutch = pi*Coefficient of Friction Clutch*Permissible Intensity of Pressure in Clutch*Inner Diameter of Clutch*((Outer Diameter of Clutch^2)-(Inner Diameter of Clutch^2))/(8*sin(Semi-Cone Angle of Clutch))
MT = pi*μ*pa*di*((do^2)-(di^2))/(8*sin(α))

What is Friction Torque on Multiple Disk Clutch?


Friction torque on a multiple disk clutch refers to the resistive torque generated by the frictional forces between the disks when the clutch is engaged. It is the torque required to overcome the friction between the contacting surfaces of multiple disks in the clutch assembly during rotation. This friction torque is crucial for transmitting power efficiently from the engine to the transmission system in vehicles and machinery.

How to Calculate Friction Torque on Cone Clutch from Constant Wear Theory given Semi-Cone Angle?

Friction Torque on Cone Clutch from Constant Wear Theory given Semi-Cone Angle calculator uses Friction Torque on Clutch = pi*Coefficient of Friction Clutch*Permissible Intensity of Pressure in Clutch*Inner Diameter of Clutch*((Outer Diameter of Clutch^2)-(Inner Diameter of Clutch^2))/(8*sin(Semi-Cone Angle of Clutch)) to calculate the Friction Torque on Clutch, Friction Torque on Cone Clutch from Constant Wear Theory given Semi-Cone Angle formula is defined as the measure of rotational force that opposes motion in a cone clutch system, influenced by the semi-cone angle, and is a critical parameter in the design and optimization of cone clutches in various mechanical systems. Friction Torque on Clutch is denoted by MT symbol.

How to calculate Friction Torque on Cone Clutch from Constant Wear Theory given Semi-Cone Angle using this online calculator? To use this online calculator for Friction Torque on Cone Clutch from Constant Wear Theory given Semi-Cone Angle, enter Coefficient of Friction Clutch (μ), Permissible Intensity of Pressure in Clutch (pa), Inner Diameter of Clutch (di), Outer Diameter of Clutch (do) & Semi-Cone Angle of Clutch (α) and hit the calculate button. Here is how the Friction Torque on Cone Clutch from Constant Wear Theory given Semi-Cone Angle calculation can be explained with given input values -> 2.4E+8 = pi*0.2*1012225*0.1*((0.2^2)-(0.1^2))/(8*sin(1.56905099754261)).

FAQ

What is Friction Torque on Cone Clutch from Constant Wear Theory given Semi-Cone Angle?
Friction Torque on Cone Clutch from Constant Wear Theory given Semi-Cone Angle formula is defined as the measure of rotational force that opposes motion in a cone clutch system, influenced by the semi-cone angle, and is a critical parameter in the design and optimization of cone clutches in various mechanical systems and is represented as MT = pi*μ*pa*di*((do^2)-(di^2))/(8*sin(α)) or Friction Torque on Clutch = pi*Coefficient of Friction Clutch*Permissible Intensity of Pressure in Clutch*Inner Diameter of Clutch*((Outer Diameter of Clutch^2)-(Inner Diameter of Clutch^2))/(8*sin(Semi-Cone Angle of Clutch)). Coefficient of Friction Clutch is a value that represents the frictional force between the clutch and the flywheel in a constant wear theory scenario, Permissible Intensity of Pressure in Clutch is the maximum allowed pressure in a clutch, ensuring efficient power transmission without wear and tear, according to constant wear theory, Inner Diameter of Clutch is the diameter of the clutch that remains constant during the wear process, affecting the clutch's performance and lifespan, Outer Diameter of Clutch is the maximum diameter of the clutch that remains constant during the wear process in the constant wear theory & Semi-Cone Angle of Clutch is the angle at which the clutch wears out uniformly according to the Constant Wear Theory in a semi-cone shaped clutch.
How to calculate Friction Torque on Cone Clutch from Constant Wear Theory given Semi-Cone Angle?
Friction Torque on Cone Clutch from Constant Wear Theory given Semi-Cone Angle formula is defined as the measure of rotational force that opposes motion in a cone clutch system, influenced by the semi-cone angle, and is a critical parameter in the design and optimization of cone clutches in various mechanical systems is calculated using Friction Torque on Clutch = pi*Coefficient of Friction Clutch*Permissible Intensity of Pressure in Clutch*Inner Diameter of Clutch*((Outer Diameter of Clutch^2)-(Inner Diameter of Clutch^2))/(8*sin(Semi-Cone Angle of Clutch)). To calculate Friction Torque on Cone Clutch from Constant Wear Theory given Semi-Cone Angle, you need Coefficient of Friction Clutch (μ), Permissible Intensity of Pressure in Clutch (pa), Inner Diameter of Clutch (di), Outer Diameter of Clutch (do) & Semi-Cone Angle of Clutch (α). With our tool, you need to enter the respective value for Coefficient of Friction Clutch, Permissible Intensity of Pressure in Clutch, Inner Diameter of Clutch, Outer Diameter of Clutch & Semi-Cone Angle of Clutch and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.
How many ways are there to calculate Friction Torque on Clutch?
In this formula, Friction Torque on Clutch uses Coefficient of Friction Clutch, Permissible Intensity of Pressure in Clutch, Inner Diameter of Clutch, Outer Diameter of Clutch & Semi-Cone Angle of Clutch. We can use 3 other way(s) to calculate the same, which is/are as follows -
  • Friction Torque on Clutch = Coefficient of Friction Clutch*Operating Force for Clutch*(Outer Diameter of Clutch+Inner Diameter of Clutch)/(4*sin(Semi-Cone Angle of Clutch))
  • Friction Torque on Clutch = Coefficient of Friction Clutch*Operating Force for Clutch*Pairs of Contacting Surface of Clutch*(Outer Diameter of Clutch+Inner Diameter of Clutch)/4
  • Friction Torque on Clutch = pi*Coefficient of Friction Clutch*Permissible Intensity of Pressure in Clutch*Inner Diameter of Clutch*((Outer Diameter of Clutch^2)-(Inner Diameter of Clutch^2))/8
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